U.S. patent application number 09/781565 was filed with the patent office on 2001-09-06 for fluid-filled elastic mount whose orifice passage has sufficiently large cross sectional area exhibits improved fluid-tightness.
Invention is credited to Okanaka, Takehiro, Tanahashi, Hiroaki.
Application Number | 20010019099 09/781565 |
Document ID | / |
Family ID | 18565883 |
Filed Date | 2001-09-06 |
United States Patent
Application |
20010019099 |
Kind Code |
A1 |
Okanaka, Takehiro ; et
al. |
September 6, 2001 |
Fluid-filled elastic mount whose orifice passage has sufficiently
large cross sectional area exhibits improved fluid-tightness
Abstract
A fluid-filled elastic mount including an elastic body
elastically connecting a first mounting member and a cylindrical
second mounting members for fluid-tightly closing one open end of
the second mounting member, a partition and a closure members
superposed on each other and fixed at their peripheral portions to
the other open end of the second mounting member, by calking, to
provide on one side of the partition member a pressure receiving
chamber partially defined by the elastic body and on the other side
of the partition member an equilibrium chamber partially defined by
a flexible diaphragm fixed to the closure member. These chambers
are filled with a non-compressible fluid. The partition member has
a cylindrical positioning shoulder, while the closure member has a
cylindrical wall portion which is press-fitted onto the positioning
shoulder of the partition member, so that the partition and closure
member are positioned relative to each other in their diametric
direction. The partition member also has an axial protrusion
extending in its circumferential direction and diametrically
opposed to the cylindrical wall portion of the closure member with
a radial spacing therebetween to define an annular passage, and a
partition wall disposed at a circumferential portion of the annular
passage to fluid-tightly intercept the annular passage. The annular
passage is held in fluid communication with the pressure-receiving
chamber through a first communication hole formed on one side of
the partition wall and with the equilibrium chamber through a
second communication hole formed on the other side of the partition
wall, to serve as an orifice passage.
Inventors: |
Okanaka, Takehiro;
(Kasugai-shi, JP) ; Tanahashi, Hiroaki;
(Nishikasugai-gun, JP) |
Correspondence
Address: |
ROSSI & ASSOCIATES
P.O. Box 826
Ashburn
VA
20146-0826
US
|
Family ID: |
18565883 |
Appl. No.: |
09/781565 |
Filed: |
February 9, 2001 |
Current U.S.
Class: |
248/562 ;
248/634 |
Current CPC
Class: |
F16F 13/105
20130101 |
Class at
Publication: |
248/562 ;
248/634 |
International
Class: |
F16M 013/00 |
Foreign Application Data
Date |
Code |
Application Number |
Feb 21, 2000 |
JP |
2000-42870 |
Claims
What is claimed is:
1. A fluid-filled elastic mount including (a) a first mounting
member and a generally cylindrical second mounting member, which
are spaced apart from each other in an axial direction of said
second mounting member, (b) an elastic body elastically connecting
said first and second mounting members so as to fluid-tightly close
one of axially opposite open ends of said second mounting member,
(c) a partition member made of metal and extending in a direction
perpendicular to said axial direction, (d) a closure member made of
metal and having a central through hole and a flexible diaphragm
fluid-tightly closing said central through hole, said partition
member and said closure member being superposed on each other and
fixed at their peripheral portions to the other of axially opposite
open ends of said second mounting member, by calking, so as to
provide on one of opposite sides of said partition member a
pressure receiving chamber which is partially defined by said
elastic body and filled with a non-compressible fluid, and on the
other of opposite sides of said partition member an equilibrium
chamber which is partially defined by said flexible diaphragm and
filled with the non-compressible fluid, and (e) an orifice passage
for fluid communication between said pressure receiving chamber and
said equilibrium chamber, said orifice passage being formed between
said partition and closure members so as to extend in a
circumferential direction of said partition and closure members,
wherein an improvement comprises: said partition member including
an axial protrusion formed at a radially intermediate portion
thereof and having an outer circumferential surface extending in
said circumferential direction thereof, and a cylindrical
positioning shoulder located radially inwardly of said peripheral
portion thereof, said closure member including an integrally formed
cylindrical wall portion located radially inwardly of and
protruding axially outwardly from said peripheral portion thereof,
and an integrally formed annular plate portion extending radially
inwardly from a protruding open end portion of said cylindrical
wall portion, said partition and closure members being superposed
on each other such that said cylindrical wall portion of said
closure member is partially press-fitted onto an outer
circumferential surface of said cylindrical positioning shoulder of
said partition member so as to be positioned relative to said
partition member in a diametric direction thereof, and that the
annular plate portion of said closure member being superposed at an
inner peripheral portion thereof on a protruding end face of said
axial protrusion of said partition member to thereby provide an
annular passage partially defined by and circumferential extending
between said cylindrical wall portion of said closure member and
said axial protrusion of said partition member which are opposed to
each other in said diametric direction, said annular groove
including a partition wall formed at a circumferential portion
thereof, said partition wall protruding radially outwardly from the
side of said partition member toward the side of said closure
member such that said partition wall is elastically pressed against
the side of said closure member to thereby fluid tightly intercept
said annular passage in a circumferential direction thereof; and
said annular passage being held in fluid communication with said
pressure receiving chamber through a first communication hole
formed on one of circumferentially opposite sides of said partition
wall and with said equilibrium chamber through a second
communication hole formed on the other side of said partition wall,
to serve as said orifice passage.
2. A fluid-filled elastic mount according to claim 1, wherein said
partition and closure members are pressed against each other by an
axial compression force caused by said calking, which force acts on
the interfaces between an axially protruding end face of said
partition wall and the annular plate portion of the closure member
so that the partition wall of the partition member is held in
elastically pressing contact at its axially protruding end face
with said annular plate portion of said closure member.
3. A fluid-filled elastic mount according to claim 1, wherein, said
first and second communication holes are formed on the side of said
partition member.
4. A fluid-filled elastic mount according to claim 3, wherein said
first communication hole is constituted by a through hole formed
through said partition member, which is located on one of opposite
sides of the partition wall in the circumferential direction and is
located radially inwardly of said positioning shoulder, and said
second communication hole is constituted by a small-diameter
portion of the annular protrusion located on the other side of the
partition wall.
5. A fluid-filled elastic mount according to claim 1, wherein said
cylindrical positioning shoulder is integrally formed with said
partition member.
6. A fluid-filled elastic mount according to claim 1, wherein said
cylindrical positioning shoulder is formed of a rubber
material.
7. A fluid-filled elastic mount according to claim 1, wherein said
partition and closure member are both formed of metal by
pressing.
8. A fluid-filled elastic mount according to claim 1, wherein said
partition member further includes a central through hole and an
elastic movable plate fluid-tightly closing said through hole, said
elastic movable plate being elastically deformable based on a fluid
pressure difference between said pressure receiving chamber and
said equilibrium chamber, said fluid pressures of said pressure
receiving and equilibrium chambers act on opposite surfaces of said
movable rubber plate, respectively.
9. A fluid-filled elastic mount according to claim 1, wherein said
axial protrusion of said partition member is formed of a rubber
material, and said partition wall is integrally formed with said
axial protrusion.
10. A fluid-filled elastic mount according to claim 9, wherein said
axial protrusion includes a reinforcing member embedded therein,
said reinforcing member being formed as an integral part of said
partition member.
11. A fluid-filled elastic mount according to claim 1, further
comprising a sealing rubber layer which is bonded to an inner
circumferential surfaces of said cylindrical wall portion and said
annular plate portion of said closure member, and which is
integrally formed with said flexible diaphragm, said closure member
being press-fitted at said cylindrical wall portion thereof to said
cylindrical positioning shoulder of said partition member via said
sealing rubber layer, and being press-fitted at said annular plate
portion thereof to the protruding end face of said axial protrusion
of said partition member via said sealing rubber layer, said
partition wall of said partition member being pressed against said
closure member via said sealing rubber layer.
12. A fluid-filled elastic mount according to claim 1, wherein said
positioning shoulder has a generally cylindrical outer
circumferential surface extending in the axial direction with a
generally constant diameter, and has a rounded edge at a protruding
end face thereof.
13. A fluid-filled elastic mount according to claim 1, wherein said
cylindrical positioning shoulder has a tapered outer
circumferential surface extending in the axial direction with a
diameter gradually reduced in the axially extending direction
thereof.
14. A fluid-filled elastic mount according to claim 1, wherein an
outer circumferential surface of said partition wall is positioned
not to protrude radially outwardly from an outer circumferential
surface of said cylindrical positioning shoulder, and said
cylindrical wall portion includes a local portion adapted to
contact with the outer circumferential surface of said partition
wall and protruding radially inwardly from the outer
circumferential surface of said cylindrical positioning shoulder so
as to be elastically pressed against the outer circumferential
surface of said partition wall in the radial direction thereof.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] The present invention relates generally to a fluid-filled
elastic mount adapted to provide a vibration damping effect on the
basis of flows of a fluid filling the fluid chamber thereof. More
particularly, the present invention is concerned with such a
fluid-filled elastic mount that is novel in construction and which
is suitably used as an engine mount, a body mount or other mounts
for an automotive vehicle.
[0003] 2. Description of the Related Art
[0004] As one type of a vibration damping device such as a
vibration damping coupling (bushing) or mount, which is interposed
between two members of a vibration system for flexibly connecting
these two members or mounting one of these members on the other
member in a vibration damping manner, there is known a fluid-filled
elastic mount wherein a first metallic mounting member and a second
metallic mounting member having a hollow cylindrical configuration
are spaced apart from each other such that the first mounting
member is disposed on the side of one of opposite open ends of the
second mounting member, and are elastically connected to each other
by an elastic body, whereby the one open end of the second mounting
member is fluid tightly closed by the elastic body. The other open
end of the second mounting member is fluid tightly closed by a
flexible rubber diaphragm, to thereby define a fluid chamber
between the elastic body and the flexible diaphragm, which is
filled with a non-compressible fluid. The fluid-filled elastic
mount further includes a metallic partition member supported by the
second mounting member, which is adapted to divide the fluid
chamber such that a pressure-receiving chamber which is partially
defined by the elastic body is formed on one side of the partition
member, while a variable-volume equilibrium chamber which is
partially defined by the flexible diaphragm formed on the other
side of the partition member. These pressure receiving and
equilibrium chambers communicate with each other by an orifice
passage. Upon application of vibrational loads between the first
and second mounting members, a pressure of the fluid in the
pressure receiving chamber changes due to elastic deformation of
the elastic body, generating a pressure difference of the fluid
between the pressure receiving and equilibrium chambers. Based on
this pressure difference of the fluid, the non-compressible fluid
forcedly flows through the orifice passage between the pressure
receiving and equilibrium chambers, so that the fluid-filled
elastic mount can exhibits an excellent vibration damping effect,
owing to resonance or flows of the fluid flowing through the
orifice passage. In the light of this excellent vibration damping
effect, the elastic mount of this type is favorably used as an
engine mount or a body mount for an automotive vehicle, for
example.
[0005] Such a fluid-filled elastic mount can exhibit a desired
vibration damping effect based on the resonance or flows of the
fluid flowing through the orifice passage, by suitably tuning or
determining a length and a cross sectional area of the orifice
passage. In order to exhibit the excellent vibration damping effect
of the elastic mount, the orifice passage needs to be made longer
enough to assure a sufficiently large amount or mass of the fluid
flowing through the orifice passage. To this end, the orifice
passage may be conventionally constructed by using the partition
member and an annular closure member made of metal, which is bonded
at its outer peripheral portion to the periphery of the flexible
diaphragm upon vulcanization of a rubber material for forming the
flexible diaphragm. The annular closure member and the partition
member are superposed on each other and fixed by calking at their
peripheral portions to the other open end portion of the second
mounting member which is remote from the first mounting member, to
thereby define therebetween an annular passage extending in the
circumferential direction thereof. The annular passage includes a
partition wall formed at a circumferential portion thereof so as to
fluid-tightly divide the annular passage in the circumferential
direction, and a first and a second communication hole located on
the opposite sides of the partition wall, so that the annular
passage is held in fluid communication through the first and second
communication hole with the pressure receiving chamber and the
equilibrium chamber, respectively, thereby providing the orifice
passage. According to this conventional structure of the orifice
passage, the orifice passage is effectively and easily formed at
the radially outward portion of the fluid chamber, so as to extend
in the circumferential direction of the second mounting member with
a circumferential length which is slightly smaller than the
circumference of the second mounting member.
[0006] However, the conventional orifice structure may possibly
suffer from a problem of insufficient fluid tightness at the
partition wall portion, resulting in undesirable fluid
communication between both ends of the orifice passage located on
the opposite sides of the partition wall. This drawback makes it
impossible to obtain a desired length of the orifice passage,
resulting in deterioration of the vibration damping effect of the
elastic mount.
[0007] To cope with the conventionally experienced problem, the
present assignee has proposed an improved orifice structure as
disclosed in JP-A-8-128491, wherein a partition wall made of an
elastic body is formed at a circumferential portion of the annular
passage so as to protrude from the partition member toward the
closure member with a radial length which is reduced in a direction
toward the closure member. That is, the partition wall has an
inclined outer circumferential surface. The closure member is also
arranged to have an inclined inner circumferential surface
corresponding to the inclined outer circumferential surface of the
partition wall. The inclined inner circumferential surface of the
closure member is superposed on and forcedly pressed against the
inclined outer circumferential surface of the partition wall, owing
to the calking force applied between the partition and closure
members. The inclined inner circumferential surface of the closure
member which defines outer circumferential surface of the orifice
passage inevitably causes undesirable reduction in the cross
sectional area of the orifice passage, possibly leading to
difficulty in assuring a required insufficient vibration damping
effect of the elastic mount. Thus, the conventional fluid-filled
elastic mount as descried above, still has some room for
improvement.
SUMMARY OF THE INVENTION
[0008] It is therefore an object of the invention to provide a
fluid-filled elastic mount which is novel in construction and which
permits an easy formation of an orifice passage that is partially
defined by and between a partition member and a closure member
which are superposed on each other and fixed by calking to a second
mounting member. The orifice passage extends in the circumferential
direction of the partition and closure members with a
circumferential length slightly smaller than a circumference of
these members and with a sufficiently large cross sectional area.
The orifice passage also exhibits an excellent fluid-tightness at a
partition wall portion, thereby preventing undesirable
fluid-leakage or fluid-communication between both ends of the
orifice passage located on the opposite sides of the partition
wall.
[0009] The above object of the invention may be achieved according
to the principle of the invention, which provide a fluid-filled
elastic mount including (a) a first mounting member and a generally
cylindrical second mounting member, which are spaced apart from
each other in an axial direction of the second mounting member, (b)
an elastic body elastically connecting the first and second
mounting members so as to fluid-tightly close one of axially
opposite open ends of the second mounting member, (c) a partition
member made of metal and extending in a direction perpendicular to
the axial direction, (d) a closure member made of metal and having
a central through hole and a flexible diaphragm fluid-tightly
closing the central through hole, the partition member and the
closure member being superposed on each other and fixed at their
peripheral portions to the other of axially opposite open ends of
the second mounting member, by calking, so as to provide on one of
opposite sides of the partition member a pressure receiving chamber
which is partially defined by the elastic body and filled with a
non-compressible fluid, and on the other of opposite sides of the
partition member an equilibrium chamber which is partially defined
by the flexible diaphragm and filled with the non-compressible
fluid, and (e) an orifice passage for fluid communication between
the pressure receiving chamber and the equilibrium chamber, the
orifice passage being formed between the partition and closure
members so as to extend in a circumferential direction of the
partition and closure members, wherein an improvement comprises:
the partition member including an axial protrusion formed at a
radially intermediate portion thereof and having an outer
circumferential surface extending in the circumferential direction
thereof, and a cylindrical positioning shoulder located radially
inwardly of the peripheral portion thereof, the closure member
including an integrally formed cylindrical wall portion located
radially inwardly of and protruding axially outwardly from the
peripheral portion thereof, and an integrally formed annular plate
portion extending radially inwardly from a protruding open end
portion of the cylindrical wall portion, the partition and closure
members being superposed on each other such that the cylindrical
wall portion of the closure member is partially press-fitted onto
an outer circumferential surface of the cylindrical positioning
shoulder of the partition member so as to be positioned relative to
the partition member in a diametric direction thereof, and that the
annular plate portion of the closure member being superposed at an
inner peripheral portion thereof on a protruding end face of the
axial protrusion of the partition member to thereby provide an
annular passage partially defined by and circumferential extending
between the cylindrical wall portion of the closure member and the
axial protrusion of the partition member which are opposed to each
other in the diametric direction, the annular groove including a
partition wall formed at a circumferential portion thereof, the
partition wall protruding radially outwardly from the side of the
partition member toward the side of the closure member such that
the partition wall is elastically pressed against the side of said
closure member to thereby fluid tightly intercept the annular
passage in a circumferential direction thereof; and the annular
passage being held in fluid communication with the pressure
receiving chamber through a first communication hole formed on one
of circumferentially opposite sides of the partition wall and with
the equilibrium chamber through a second communication hole formed
on the other side of the partition wall, to serve as the orifice
passage.
[0010] In the fluid-filled elastic mount of the present invention
constructed as described above, the partition and closure members
are superposed on and assembled with each other in the axial
direction such that the cylindrical wall portion of the closure
member is press-fitted onto the positioning shoulder of the
partition member, so that the partition and closure members are
fixed by calking to the second mounting member with these members
positioned relative to each other in a substantially coaxial or
concentric relationship. In this condition, the suitably
dimensioned outer circumferential surface of the partition wall of
the partition member and the suitably dimensioned inner
circumferential surface of the cylindrical wall portion of the
closure member are elastically pressed against each other with the
partition wall compressed in the radial direction by a
predetermined compression amount. Therefore, the engine mount of
the present invention effectively and stably assures that the
partition wall is held in elastically pressing contact at its outer
circumferential surface with the inner circumferential surface of
the outer cylindrical wall portion, without needing a specific
operation for positioning the partition and closure members
relative to each other in the diametric direction. In addition,
with the thus assembled partition and closure members being fixed
by calking to the second mounting member, an axial compression
force caused by the calking acts on the interfaces between an
axially protruding end face of the partition wall of the partition
member and the annular plate portion of the closure member, so that
the partition wall and the annular plate portion of the closure
member are pressed against each other with high stability.
[0011] That is, the present engine mount assures the pressing
contact of the partition wall with the cylindrical wall portion of
the closure member with high stability, in the condition where the
cylindrical wall portion of the closure member being press-fitted
onto the positioning shoulder of the partition member, without
requiring the specific operation for positioning the partition and
closure members relative to each other in the diametrical
direction. This makes it possible to substantially completely
eliminate the conventionally experienced problem of the undesirable
fluid-leakage or communication between both ends of the orifice
passage, resulting in desired vibration damping effect of the
engine mount based on the flows of the fluid flowing through the
orifice passage, with high stability.
[0012] According to one preferred form of the present invention,
the first and second communication holes are formed on the side of
the partition member. This makes it possible to eliminate a
requirement for positioning the partition and closure members
relative to each other in the circumferential direction, leading to
further improved efficiency of assembling the partition and closure
members. For instance, the first communication hole may be
effectively constituted by a through hole formed through the
partition member, which is located on one of opposite sides of the
partition wall in the circumferential direction, and which is also
located radially inwardly of the positioning shoulder. This through
hole allows one of circumferentially opposite ends of the orifice
passage to communicate with the pressure-receiving chamber, thereby
functioning as the first communication hole. The second
communication hole, for example, may be effectively constituted by
a small-diameter portion of the annular protrusion located on the
other side of the partition wall. Namely, the outer circumferential
surface of the axial protrusion, which partially defines an inner
circumferential surface of the orifice passage, is partially
retracted radially inwardly at a circumferential portion located on
the other side of the partition wall. The small diameter portion of
the annular protrusion allows the other end of the orifice passage
to communicate with the equilibrium chamber, thereby functioning as
the second communication hole.
[0013] In the present invention, the positioning shoulder of the
partition member may possibly be formed of a rubber material, a
resin material or other suitable materials, and fixedly secured to
the partition member. Preferably, the positioning shoulder is
integrally formed with the partition member. The positioning
shoulder formed as an integral part of the partition member made of
metal, permits a higher degree of stability and precision of the
positioning of the partition and cylindrical members relative to
each other, in comparison with the positioning shoulder formed of
the elastic body or the resin material, resulting in a further
improved degree of reliability in preventing the mutual
communication between the both ends of the orifice passage.
[0014] According to another preferred form of this invention, the
partition and closure members are both formed of a metallic
material by pressing. This arrangement assures an improved
efficiency and reduced cost of manufacture of these two members.
For instance, the partition and closure members may be effectively
formed of a ferrous metal or other metallic materials such as an
aluminum alloy. Further, any other suitable operations other than
the pressing operation may be employed for forming the partition
and closure members.
[0015] According to a further preferred form of this invention, the
partition member further includes a central through hole and an
elastic movable plate fluid-tightly closing the central through
hole, the elastic movable plate being elastically deformable based
on a fluid pressure difference between the pressure receiving and
equilibrium chambers, which fluid pressures act on opposite surface
of the elastic movable plate, respectively. This elastic
deformation of the elastic movable plate functions to offset or
absorb the fluid pressure change in the pressure receiving chamber,
upon application of the high frequency vibrations causing a
substantially no flow of the fluid flowing through the orifice
passage. In the presence of the elastic movable plate, the elastic
mount according to this preferred form of the invention can exhibit
an improved vibration damping effect with respect to the high
frequency vibrations.
[0016] According to a still further preferred form of the present
invention, the axial protrusion of the partition member is formed
of a rubber material, and the partition wall is integrally formed
with the axial protrusion. In this preferred form of the invention,
the axial protrusion and the partition wall are formed as an
integral elastic body. This arrangement is effective to provide the
orifice passage which exhibits an improved fluid-tight sealing, and
which is free from the problem of the fluid-leakage or
fluid-communication between the both ends of the orifice passage,
with high stability. In this case, the axial protrusion preferably
includes a reinforcing plate embedded therein and formed as an
integral part of the partition member, in order to assure desired
stability and rigidity of the axial protrusion. When the partition
member includes the elastic movable plate according to the
aforementioned preferred form of the invention, preferably, the
elastic movable plate is also integrally formed with the axial
protrusion and the partition wall.
[0017] According to a yet further preferred form of this invention,
there is provided a sealing rubber layer which is bonded to inner
circumferential surfaces of the cylindrical wall portion and the
annular plate portion of the closure member, and which is
integrally formed with the flexible diaphragm, the closure member
being press-fitted at the cylindrical wall portion thereof to the
cylindrical positioning shoulder of the partition member via the
sealing rubber layer, and being press-fitted at the annular plate
portion thereof to the protruding end face of the axial protrusion
of the partition member via the sealing rubber layer, the partition
wall of the partition member being pressed against or being held in
pressing contact with the closure member via the sealing rubber
layer.
[0018] In this preferred form of the present invention, a clearance
possibly formed between the partition and closure members due to
the dimensional tolerances of the partition and closure members, is
effectively absorbed by the sealing rubber layer interposed between
and compressed by the partition and closure members, resulting in
further improved fluid-tight sealing of the orifice passage.
Preferably, the sealing rubber layer is used together with the
axial protrusion and the partition wall, which are formed as the
integral elastic body as in the aforementioned preferred form of
the invention.
[0019] The positioning shoulder may have a generally cylindrical
outer circumferential surface extending in the axial direction with
a generally constant diameter. Alternatively, the positioning
shoulder may have a tapered outer circumferential surface extending
in the axial direction with a diameter gradually reduced in the
axially extending direction thereof. In the latter case, the
tapered positioning shoulder may further facilitate the operation
for press-fitting the cylindrical wall portion of the closure
member to the positioning shoulder. In the farmer case, the
generally cylindrical outer circumferential surface may preferably
be arranged to have a rounded edge at its protruding end face, so
that the outer circumferential surface of the positioning shoulder
functions as a guide surface along which the cylindrical wall
portion of the closure member is pushed toward the partition
member, upon press-fitting the closure member to the partition
member.
[0020] According to a still yet further preferred form of this
invention, the partition wall formed in the partition member may be
dimensioned such that the outer circumferential surface of the
partition wall is aligned in the axial direction with the outer
circumferential surface of the positioning shoulder, or
alternatively is retracted radially inwardly from the outer
circumferential surface of the positioning shoulder with a slight
amount of radial distance. Namely, the outer circumferential
surface of the partition wall is located not to protrude radially
outwardly from the outer circumferential surface of the cylindrical
positioning shoulder. The cylindrical wall portion includes a local
portion adapted to contact with the outer circumferential surface
of the partition wall and protruding radially inwardly from the
outer circumferential surface of the cylindrical positioning
shoulder, so as to be elastically pressed against or to be held in
pressing contact with the outer circumferential surface of the
partition wall in the radial direction of the partition and closure
members.
[0021] In this preferred form of the invention, a mold used for
forming the partition wall by vulcanizing a rubber material, never
has an overhang, resulting in improved efficiency in vulcanizing
and pressing operations for manufacturing the partition and closure
members.
BRIEF DESCRIPTION OF THE DRAWINGS
[0022] The above and other objects, features advantages and
technical and industrial significance of the present invention will
be better understood by reading the following detailed description
of the present preferred embodiments or modes of the invention when
considered in connection with the accompanying drawings in
which:
[0023] FIG. 1 is an elevational view in axial cross section of a
fluid-filled elastic mount in the form of an automotive vehicle
engine mount constructed according to one embodiment of this
invention;
[0024] FIG. 2 is an elevational view in axial cross section of an
integral vulcanized product used in the engine mount of FIG. 1;
[0025] FIG. 3 is an elevational plane view of a partition member
used in the engine mount of FIG. 1;
[0026] FIG. 4 is a cross sectional view of the partition member
taken along line 4-4 of FIG. 3;
[0027] FIG. 5 is a cross sectional view of the partition member
taken along line 5-5 of FIG. 3;
[0028] FIG. 6 is an elevational view in axial cross section of a
closure member used in the engine mount of FIG. 1;
[0029] FIG. 7 is a fragmentally view in axial cross section showing
one modification of the partition member used in the engine mount
of FIG. 1;
[0030] FIG. 8 is a fragmentally view in axial cross section showing
a another modification of the partition member used in the engine
mount of FIG. 1;
[0031] FIG. 9 is a fragmentally view in axial cross section showing
a yet another modification of the partition member used in the
engine mount of FIG. 1; and
[0032] FIG. 10 is an elevational plane view of the partition member
of FIG. 9.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
[0033] Referring first to FIG. 1, an engine mount 10 for an
automotive vehicle is shown as one embodiment of the fluid-filled
elastic mount of the present invention. This engine mount 10
includes an inner mounting member 12 as a first mounting member and
an outer mounting member 14 as a second mounting member, which
members 12, 14 are both made of metallic materials and are spaced
apart from each other in their axial direction. The inner and outer
mounting members 12, 14 are elastically connected to each other by
an elastic body 16 interposed therebetween. The present engine
mount 10 is installed on the vehicle such that the inner mounting
member 12 is attached to the power unit of the vehicle (not shown),
while the outer mounting member 14 is attached to the body of the
vehicle (not shown), so that the power unit is suspended from the
body in a vibration damping or isolating manner. The engine mount
10 is installed in position where the upper side of the engine
mount 10 as seen in FIG. 1 is located radially inwardly of the
lower side of the engine mount 10 as seen in FIG. 1. When the
engine mount 10 is installed on the vehicle as described above, the
weight of the power unit acts on the engine mount 10 in the
vertical direction as seen in FIG. 1. This static load causes a
certain amount of elastic deformation of the elastic member 16 so
that the inner mounting member 12 is displaced by a suitable amount
relative to the outer mounting member 14 in the vertically downward
direction. The engine mount 10 receives a vibrational load
primarily in the substantially vertical direction as seen in FIG.
1.
[0034] Described in detail, the inner mounting member 12 is a
tapered solid cylindrical member whose diameter increases in an
axially upward direction as seen in FIG. 1. Namely, the inner
mounting member 12 includes an axially upper portion serving as a
tapered portion 18 and an axially lower portion formed with a
threaded hole 20 open in the axially lower end face of the inner
mounting member 12. The inner mounting member 12 is attached to the
power unit (not shown) by a bolt 22 which is screwed in the
threaded hole 20.
[0035] The outer mounting member 14 is a thin walled generally
hollow cylindrical member whose inner diameter is sufficiently
larger than the outside diameter of the inner mounting member 12.
The outer mounting member 14 includes at its axially lower half end
a tapered portion 24 whose diameter is reduced in the axially
downward direction as seen in FIG. 1, and at its axially upper half
end a large-diameter portion 26 which extends in the axial
direction with a generally constant inner and outer diameters. The
large-diameter portion 26 includes a shoulder 28 integrally formed
at its axially upper end potion so as to extend radially outwardly
from the axially upper end portion. The shoulder 28 has a
peripheral portion which is bent in an axially upward direction to
thereby integrally form a calking portion 30 which extends in the
axially upward direction with a cylindrical form.
[0036] The outer mounting member 14 is disposed radially outwardly
of the inner mounting member 12 in substantially coaxial
relationship with the member 12, with a given radial spacing
therebetween, such that the axially lower end portion of the inner
mounting member 12 protrudes axially outwardly from the outer
mounting member 14.
[0037] With the inner and outer mounting member 12, 14 are disposed
relative to each other as described above, the outer
circumferential surface of the tapered portion 18 of the inner
mounting member 12 and the inner circumferential surface of the
tapered portion 24 of the outer mounting member 14 are opposed to
each other, and are elastically connected to each other by the
elastic body 16 which is interposed between and bonded to these
opposite surfaces upon vulcanization of a rubber material for
forming the elastic body 16. Thus, the inner and outer mounting
members 12, 14 and the elastic body 16 elastically connecting these
two members 12, 14 are provided as an integral vulcanized
intermediate product 32. The elastic body 16 has a generally
tapered thick-walled cylindrical shape, and is bonded at an inner
circumferential surface thereof to the outer circumferential
surface of the tapered portion 18 of the inner mounting member 12
and at an outer circumferential surface thereof to the inner
circumferential surface of the tapered portion 24 of the outer
mounting member 14.
[0038] With the elastic body 16 bonded by vulcanization to the
inner and outer mounting members 12, 14 as described above, the
small-diameter open end portion of the outer mounting member 14,
i.e., the axially lower open end portion as seen in FIG. 1, is
fluid tightly closed by the elastic body 16 and the inner mounting
member 12. The inner circumferential surface of the outer mounting
member 14 is substantially entirely covered by a sealing rubber
layer 34 integrally formed with the elastic body 16 and bonded to
the inner circumferential surface of the outer mounting member 14
upon vulcanization of a rubber material to form the sealing rubber
layer 34.
[0039] On the other hand, the large-diameter open-end portion of
the outer mounting member 14, i.e., the axially upper open end
portion as seen in FIG. 1, is fluid tightly closed by a partition
member 36 and a closure member 38 which are superposed in this
order on the large-diameter open-end portion of the outer mounting
member 14.
[0040] Referring next to FIGS. 3-5, the partition member 36
consists of a partition plate 40 made of metal and having an
annular plate-like shape, and a movable rubber plate 44 for
fluid-tightly closing a central opening 42 as a central through
hole of the partition plate 40 which will be described later. The
outer peripheral portion of the partition plate 40 serevs as an
outward flange portion 46 having an annular plate-like shape. The
inner peripheral portion of the outward flange portion 46 is bent
at substantially right angle so as to protrude axially outward or
upward direction, thereby providing a positioning stepped portion
48 having a cylindrical shape, as a cylindrical positioning
shoulder. The protruding end portion of the positioning stepped
portion 48 is bent at a substantially right angle so as to extend
radially inward direction, thereby providing an annular bottom wall
portion 50 having a relatively large width. The inner peripheral
portion of the annular bottom wall portion 50 is also bent at a
substantially right angle so as to protrude the axially upward
direction, thereby providing a cylindrical inner wall portion 52.
The protruding end portion of the cylindrical inner wall portion 52
is bent radially inwardly by a small amount of distance. The
cylindrical inner wall portion 52 is bent radially inwardly by a
small amount of distance. The cylindrical inner wall portion 52
defines the above-mentioned central opening 42 of the partition
plate 40, which opening 42 have a relatively large diameter.
[0041] The movable rubber plate 44 has a disk-like shape with a
generally constant wall thickness, and is bonded at its peripheral
portion to the cylindrical inner wall portion 52 of the partition
plate 40, upon vulcanization of a rubber material to form the
movable rubber plate 44, to thereby fluid-tightly close the central
opening 42 of the partition plate 40. The partition member 36 also
includes an annular rubber block 54 disposed radially inner-half
portion of the annular bottom wall portion 50 of the partition
plate 40 and extending over the circumference of the annular bottom
wall portion 50. The annular rubber block 54 is integrally formed
with the peripheral portion of the movable rubber plate 44, and is
bonded to the annular bottom wall portion 50 and the inner
cylindrical wall portion 52, upon vulcanization of a rubber
material to form the annular rubber block 54, so as to protrude in
the axially upward direction from the annular bottom wall portion
50. That is, the annular rubber block 54 serevs as an axial
protrusion of the partition member. In the present embodiment, the
annular rubber block 54 and the movable rubber plate 44 are formed
as an integral elastic body, and the inner cylindrical wall portion
52 of the partition member 36 is embedded within integral elastic
body. That is, the inner cylindrical wall portion 52 of the
partition plate 40 functions as a reinforcing member.
[0042] The annular rubber block 54 has a radially outward
protruding portion integrally formed at a circumferential portion
thereof. This radially outward protruding portion serevs as a
partition wall 56. More specifically, the partition wall 56 has a
given circumferential length and protrudes radially outwardly by a
given radial distance so that the radially protruding end face of
the partition wall 56 is substantially aligned with the outer
circumferential surface of the positioning stepped portion 48, in
the axial direction. The partition wall 56 has a constant axial
length that is similar to that of the annular rubber block 54. On
one of opposite sides of the partition wall 56, the wall-thickness
of the annular rubber block 54 is reduced over a predetermined
circumferential distance so as to provide a communication groove
58. Thus, the annular rubber block 54 is substantially partially
eliminated on the one side of the partition wall 56 to provide the
communication groove 58. On the other side of the partition wall
56, there is formed a communication hole 60 through the annular
bottom wall portion 50 of the partition plate 40. The annular
rubber block 54 has sealing lips 62, 64 as integral parts thereof.
The sealing lip 62 is formed on outer peripheral portion of the
axially upper end face of the annular rubber block 54 so as to
extend substantially continuously in the circumferential direction
of the annular rubber block 54, except the circumferential portion
of the annular rubber block 54 where the communication groove 58 is
formed. The sealing lip 62 is formed at the axially upper end face
of the partition wall 56 so as to extend continuously in the radial
direction of the partition wall 56.
[0043] Referring next to FIG. 6, the closure member 38 consists of
a closure metallic member 66 and a flexible rubber layer 70 adapted
to close a central through hole 68 of the closure metallic member
66, which will be described later. The outer peripheral portion of
the closure metallic member 66 serves as an outward flange portion
72 having an annular plate-like shape. The inner peripheral portion
of the outward flange portion 72 is bent at a substantially right
angle so as to protrude axially outward or upward direction,
thereby providing an outer cylindrical wall portion 74 having a
cylindrical shape. The protruding end portion of the outer
cylindrical wall portion 74 is bent at a substantially right angle
so as to extend radially inward direction, thereby providing an
annular top wall portion 76 having a relatively large width, as a
annular plate portion. The inner peripheral portion of the annular
top wall portion 76 defines the above-mentioned central through
hole 68 of the closure metallic member 66. The outer cylindrical
wall portion 74 is arranged to have an inner diameter which is
slightly larger than the outer diameter of the positioning stepped
portion 48 of the partition plate 40, and is also arranged to
extend in the axially outward direction with an axial dimension
which is larger than the sum of the axial dimensions of the
positioning stepped portion 48 and the cylindrical inner wall
portion 52 of the partition plate 40.
[0044] The flexible rubber layer 70 generally has a thin-walled
dome-like configuration with a generally constant wall-thickness.
The flexible rubber layer 70 is open toward the partition member
36. The circumferential open-end portion of the flexible rubber
layer 70 is bonded to the annular top wall portion 76 of the
closure metallic member 66 in the process of vulcanization for
forming the flexible rubber layer 70. The inner and outer
circumferential surfaces of the outer cylindrical wall portion 74
and the annular top wall portion 76 are covered, over their
substantially entire area, by an inside sealing rubber layer 78 and
an outside sealing rubber layer 80, respectively. The inside and
outside sealing rubber layers 78, 80 are integrally formed with the
flexible rubber layer 70 and formed on and bonded to the respective
inner and outer circumferential surfaces of the outer cylindrical
wall portion 74 and the annular top wall portion 76. The inside
sealing rubber layer 80 has a shoulder 82 at an axially
intermediate portion thereof, and include a small-diameter portion
on the upper side of the shoulder 82 and a large-diameter portion
on the lower side of the shoulder 82. The large-diameter portion of
the inside sealing rubber layer 78 has an first annular sealing lip
84 integrally formed thereon and protrude radially inwardly
therefrom, and a second annular sealing lip 86 formed integrally on
and axially outwardly from the axial end face of the closure
metallic member 66.
[0045] That is, the partition member 36 and the closure member 38
are formed as intermediate integral vulcanized products of the
movable rubber plate 44 and the flexible rubber layer 70,
respectively. As is apparent from FIG. 1, the closure member 38 is
superposed on and assembled to the partition member 36 in their
axial directions, such that the outward flange portion 46 of the
partition plate 40 and the outward flange portion 72 of the closure
metallic member 66 are butted to each other. Thus assemble
partition and closure members 36, 38 are superposed on the shoulder
28 of the outer mounting member 14. The outer mounting member 14 is
calked at its axially end portions against the outward flange
portions 46, 72 of the partition and closure members 36, 38. In
this manner, the partition member 36 and the closure member 38 are
firmly fixed to the axially upper open-end portion of the outer
mounting member 14.
[0046] With the partition member 36 and the closure member 38
firmly fixed to the outer mounting member 14, the upper open end of
the outer mounting member 14 is fluid tightly close by these two
members 36, 38. In the thus constructed elastic mount 10, the
elastic body 16 and the flexible rubber layer 70, which are adapted
to fluid-tightly close the upper and lower open ends of the outer
mounting member 14, respectively, cooperate with the outer mounting
member 14 to define a fluid-chamber 88 filled with a suitable
non-compressible fluid. In this condition, the partition member 36
is disposed within the fluid chamber 88 so as to extend in the
direction perpendicular to the axial direction of the engine mount
10. Thus, the partition member 36 divides the fluid chamber 88 into
two sections on the axially opposite sides thereof, namely, a
pressure receiving chamber 90 partially defined by the elastic body
16 and an equilibrium chamber 92 partially defined by the flexible
rubber layer 70. Upon application of the vibration between the
inner and outer mounting members 12, 14, the pressure of the fluid
in the pressure-receiving chamber 90 varies due to elastic
deformation of the elastic body 16, while the volume of the
equilibrium chamber 92 is permitted to vary by displacement of the
flexible rubber layer 70.
[0047] The filling of the fluid chamber 88 with the
non-compressible fluid is advantageously conducted by assembling
the partition member 36 and the closure member 38 with respect to
the intermediate product 32 constituted by the inner and outer
mounting members 12, 14 the elastic body 16, in a mass of the
selected non-compressible fluid. The non-compressible fluid filling
the fluid chamber 88 preferably has a viscosity of not higher than
0.1 Pa.s., and may be preferably selected from among water,
alkylene glycol, polyalkylene glycol and silicone oil, for
instance, for enabling the engine mount 10 to exhibit an excellent
vibration damping effect on the basis of resonance of the fluid as
described below in detail.
[0048] With the partition member 36 and the closure member 38
assembled with each other as described above, the inner
circumferential surface of the annular top wall 76 of the closure
member 38 is forcedly fitted onto the outer peripheral portion of
the annular rubber block 54 of the partition member 36 via the
inside sealing rubber layer 78 interposed therebetween. In this
condition, the annular rubber block 54 of the closure member 38 and
the outer cylindrical wall portion 74 of the partition member 36
are opposed to each other in the radial direction of the elastic
mount 10 with a given radial spacing therebetween, and cooperate to
each other to partially define therebetween an annular passage 94
extending in their circumferential direction. In the thus
constructed annular passage 94, the partition wall 56 is held in
close contact at its radially outer circumferential surface with a
corresponding circumferential portion of the outer cylindrical wall
portion 74 via the inside sealing rubber layer 78 compressed
therebetween. The partition wall 56 is also held in close contact
at its axially upper end face with the annular top wall portion 76
of the closure member 38 via the inside sealing rubber layer 78
compressed therebetween. Thus, the annular passage 94 is
intercepted in the circumferential direction thereof at the
circumferential portion thereof where the partition wall 56 is
formed.
[0049] On the opposite sides of the partition wall 56, there are
suitably positioned the communication hole 60 and the communication
groove 58, respectively, so that the annular passage 94
communicates at its one of opposite end with the pressure-receiving
chamber 90 through the communication hole 60 and at the other end
with the equilibrium chamber 92 through the communication groove
58. Therefore, the annular passage 94 serves as an orifice passage
96 for fluid communication between the pressure-receiving chamber
90 and the equilibrium chamber 92, which is formed at the outer
peripheral portion of the partition member 36 so as to extend in
the circumferential direction of the partition member 36 with a
circumferential length which is slightly smaller than the
circumference of the partition member 36. As is apparent from the
above-mentioned description with respect to the present embodiment,
the engine mount 10 includes the communication hole 60 serving as a
first communication hole, and the communication groove 58 serving
as a second communication hole.
[0050] Upon assembling the partition and closure members 36, 38
with each other, the outer cylindrical wall portion 74 of the
closure metallic member 66 is press-fitted onto the positioning
stepped portion 48 of the partition plate 40. This makes it
possible to suitably position the partition and closure members 36,
38 relative to each other in their diametric directions, and to
prevent undesirable displacement of these members 36, 38 relative
to each other in their diametric directions. When the partition and
closure members 36, 38 which are assembled with each other as
described above, the inner surface of the inside sealing rubber
layer 78 fixed onto the annular top wall portion 76 of the closure
member 38 protrudes axially downwardly from the axially upper end
face of the annular rubber block 54 of the partition member 36.
Therefore, the inner surface of the inside sealing rubber layer 78
is forcedly pressed onto the upper end face of the annular rubber
block 54 with the outward flange portions 46, 72 of the partition
and closure members 36, 38 being fixed by calking to the outer
mounting member 14, thereby assuring a fluid tightness of the
orifice passage 96 with respect to the equilibrium chamber 92,
effectively.
[0051] Further, the positioning stepped portion 48 of the partition
plate 40 is arranged to have its outside diameter which is made
slightly smaller than the inside diameter of the outer cylindrical
wall portion 74 of the closure metallic member 66, and which is
made slightly larger than the inside diameter of the inside sealing
rubber layer 78 bonded to the inner surface of the outer
cylindrical wall portion 74. In this arrangement, the outer
cylindrical wall portion 74 of the closure metallic member 66 is
forcedly press-fitted onto the positioning stepped portion 48 of
the partition plate 40 with the inside sealing rubber layer 78
compressed therebetween, permitting a stable positioning of the
partition plate 40 and the closure metallic member 66 and a
fluid-tight sealing between the positioning stepped portion 48 and
the outer cylindrical wall portion 74 with the inside sealing
rubber layer 78 being compressed therebetween.
[0052] In addition, the partition wall 56 of the partition member
36 is arranged to have an outside diameter which is made slightly
smaller than the inside diameter of the outer cylindrical wall
portion 74 of the closure metallic member 66, and which is made
slightly larger than the inside diameter of the inside sealing
rubber layer 78 bonded to the outer cylindrical wall portion 74.
Therefore, the outer cylindrical wall portion 74 of the closure
metallic member 66 is forcedly press-fitted onto the outer
circumferential surface of the partition wall 56 in the diametric
direction with the inside sealing rubber layer being compressed
therebetween. The partition wall 56 of the partition member 36 is
also arranged such that the axially upper end face of the partition
wall 56 protrudes axially upwardly from the inner surface of the
inside sealing rubber layer 78 bonded to the annular top wall 76 of
the closure metallic member 66. In this arrangement, the annular
top wall portion 76 of the closure metallic member 66 is forcedly
press-fitted onto the axially upper end face of the partition wall
56 in the axial direction with the inside sealing rubber layer 78
being compressed therebetween.
[0053] As is apparent from the forgoing description, the partition
member 36 and the closure member 38 can be assembled together with
high positioning accuracy, by forcedly fitting the outer
cylindrical wall portion 74 of the closure metallic member 66 onto
the positioning stepped portion 48 of the partition plate 40 via
the inside sealing rubber layer 78 compressed therebetween. This
makes it possible to assure excellent fluid-tightness of the
orifice passage 96, effectively preventing the conventionally
experienced problem of undesirable communication of the both ends
of the fluid passage. Accordingly, the engine mount 10 constructed
according to the present embodiment can provide the orifice passage
96 having desired length and cross sectional area thereof with high
stability.
[0054] Thus, the engine mount 10 of the present embodiment can
exhibit the desired vibration damping effect with respect to the
vibrations within a predetermined frequency band with high
stability, owing to the resonance of the fluid flowing through the
orifice passage 96 that is tuned to the predetermined frequency
band. In this respect, the orifice passage 96 partially defined by
the outer circumferential surface of the annular rubber block 54 of
the partition member 36 and the outer cylindrical wall 74 of the
closure member 38 which are disposed in coaxial relationship with
each other with a predetermined radial spacing therebetween, and
which extend parallel to each other in the axial direction. This
makes it possible to obtain a sufficiently large cross sectional
area of the orifice passage 96 with high efficiency, permitting a
sufficiently large amount of the fluid to flow through the orifice
passage 96, resulting in the desired vibration damping effect with
improved efficiency.
[0055] In the engine mount 10 constructed according to the present
embodiment, the movable rubber plate 44 closing the central opening
42 of the partition plate 40 is disposed between the pressure
receiving chamber 90 and the equilibrium chamber 92 such that the
movable rubber plate 44 partially defines at its axially upper
surface the pressure receiving chamber 90 and at its axially lower
surface the equilibrium chamber 92. Upon application of
high-frequency vibrations to the engine mount 10, the movable
rubber plate 44 is elastically deformed to reduce or absorb the
pressure change of the fluid in the pressure-receiving chamber 90,
effectively avoiding a significant increase in the dynamic spring
constant or spring stiffness with respect to the high-frequency
vibrations. Thus, the engine mount 10 can also exhibit the desired
vibration damping effect with respect to the high-frequency
vibration that cannot be effectively damped based on the fluid
flows through the orifice passage 96, since the fluid is kept from
flowing through the orifice passage 96 upon application of the
high-frequency vibration. For instance, the orifice passage 96 may
be tuned to the low-frequency vibrations such as an engine shake.
In this case, the engine mount 10 exhibits an excellent vibration
damping effects with respect to the low-frequency vibrations based
on the resonance of the fluid flowing through the orifice passage
96, while exhibiting a vibration isolating effect with respect to
the high-frequency vibrations such as booming noises, based on the
elastic deformation of the movable rubber plate 44 for reducing or
absorbing the pressure change of the fluid in the pressure
receiving chamber 90.
[0056] While the present invention has been described in its
presently preferred embodiment, it is to be understood that the
invention is not limited to the details of the illustrated
embodiment, but may be otherwise modified.
[0057] While the positioning stepped portion 48 is integrally
formed with the metallic partition plate 40 in the illustrated
embodiment, such a positioning stepped portion may be formed of a
rubber material, as shown in FIG. 7. Further, the positioning
stepped portion 48 integrally formed with the metallic partition
plate 40 may be modified to have various configurations including a
rib-like shape as shown in FIG. 8.
[0058] Further, the movable rubber plate 44 is not essential to
practicing the present invention, but may be employed as needed,
taken into account required vibration damping characteristics of
the elastic mount.
[0059] The construction and material of the partition wall 56 is
not particularly limited to the illustrated embodiment, but may be
otherwise embodied. For instance, it is possible to provide a
partition wall 98 which is integrally formed with the metallic
partition plate 40 with the configuration similar to the
illustrated partition wall 56 as illustrated in FIGS. 9 and 10. In
this case, the annular rubber block 54 may also be integrally
formed with the metallic partition plate 40. The communication
groove 58 may also be integrally formed with the metallic partition
plate 40. If the movable rubber plate 44 is not needed and if the
partition wall 56 and the annular rubber block 54 are both
integrally formed with the metallic partition plate 40, the
partition member 36 is solely constituted by the metallic partition
plate 40.
[0060] The closure member 38 may further include a covering member
adapted to cover the outer surface of the flexible rubber layer 70,
for a protection of the flexible rubber layer 70.
[0061] In the illustrated embodiment, the present invention is
applied to the engine mount 10 where the power unit is suspended
from and elastically supported by the outer mounting member 14 in
the vibration isolating fashion. The present invention may be
applicable to another type of engine mount where the power unit is
placed on and supported by the body of the vehicle in the vibration
isolating fashion.
[0062] While, the illustrated embodiment of the invention takes the
form of a fluid-filled engine mount for a motor vehicle, it is to
be understood that the principle of the invention is equally
applicable to body mounts for automotive vehicles, and the other
types of fluid-filled elastic mounts for various machines and other
equipment other than automotive vehicles.
[0063] It is to be understood that the present invention may be
embodied with various other changes, modifications, and improvement
which may occur to those skilled in the art, without departing from
the spirit and scope of the invention defined in the following
claims:
* * * * *